Quantifying Myofascial Dysfunction in Post-Stroke Pain

Overview

The purpose of this study is to quantify the extent of GlycosAminoGlycan/Hyaluronic Acid (GAG/HA) accumulation using T1rho (T1ρ) MRI in the paretic versus non-paretic shoulder rotator muscles, and correlate the T1ρ Magnetic Resonance Imaging (MRI) measurements with US echo texture measurements to develop a clinic-friendly tool to infer the extent of HA accumulation; and to distinguish between latent versus active Post Stroke Shoulder Pain (PSSP) using ultrasound (US) shear strain mapping of the same muscles on the paretic side compared with the non-paretic side.

Shoulder pain is extremely common after stroke and occurs in 30-70% of patients. Chronic post stroke shoulder pain (PSSP) contributes to depression, interferes with motor recovery, and decreases quality of life. Although PSSP is thought to be caused by damage to the myofascial tissues around the shoulder joint, the pathophysiology of myofascial dysfunction and pain in PSSP has not been elucidated, leading to missed opportunities for early diagnosis, and variable success with pain management. The accumulation of HA in muscle and its fascia can cause myofascial dysfunction. HA is a GAG and a chief constituent of the extracellular matrix of muscle. In physiologic quantities, it functions as a lubricant and a viscoelastic shock absorber, enabling force transmission during muscle contraction and stretch. Reduced joint mobility and spasticity can result in focal accumulation and alteration of HA in muscle, leading to the development of taut bands, dysfunctional gliding of deep fascia and muscle layers, Reduced Range of Motion (ROM), and pain. Muscle HA concentrations can be imaged using T1ρ MRI, and myofascial dysfunction can be assessed using echo texture analysis and shear strain mapping on quantitative US, which may serve as useful biomarkers to elucidate the pathophysiology of myofascial dysfunction in PSSP.

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Eligibility

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Outcomes